CN114234373B - Control method and device of fresh air environmental control unit and fresh air environmental control unit - Google Patents

Control method and device of fresh air environmental control unit and fresh air environmental control unit Download PDF

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Publication number
CN114234373B
CN114234373B CN202111545619.7A CN202111545619A CN114234373B CN 114234373 B CN114234373 B CN 114234373B CN 202111545619 A CN202111545619 A CN 202111545619A CN 114234373 B CN114234373 B CN 114234373B
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fresh air
temperature
control unit
time period
mode
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CN114234373A (en
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郑现友
赵成寅
聂宝平
陈桂福
邱春辉
尹相宇
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Gree Electric Appliances Inc of Zhuhai
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Gree Electric Appliances Inc of Zhuhai
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/30Control or safety arrangements for purposes related to the operation of the system, e.g. for safety or monitoring
    • F24F11/46Improving electric energy efficiency or saving
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/50Control or safety arrangements characterised by user interfaces or communication
    • F24F11/61Control or safety arrangements characterised by user interfaces or communication using timers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/64Electronic processing using pre-stored data
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F11/00Control or safety arrangements
    • F24F11/62Control or safety arrangements characterised by the type of control or by internal processing, e.g. using fuzzy logic, adaptive control or estimation of values
    • F24F11/63Electronic processing
    • F24F11/65Electronic processing for selecting an operating mode
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F2110/00Control inputs relating to air properties
    • F24F2110/50Air quality properties
    • F24F2110/65Concentration of specific substances or contaminants
    • F24F2110/70Carbon dioxide
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F24HEATING; RANGES; VENTILATING
    • F24FAIR-CONDITIONING; AIR-HUMIDIFICATION; VENTILATION; USE OF AIR CURRENTS FOR SCREENING
    • F24F2130/00Control inputs relating to environmental factors not covered by group F24F2110/00
    • F24F2130/10Weather information or forecasts
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B30/00Energy efficient heating, ventilation or air conditioning [HVAC]
    • Y02B30/70Efficient control or regulation technologies, e.g. for control of refrigerant flow, motor or heating

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Signal Processing (AREA)
  • Physics & Mathematics (AREA)
  • Fuzzy Systems (AREA)
  • Mathematical Physics (AREA)
  • Human Computer Interaction (AREA)
  • Air Conditioning Control Device (AREA)
  • Ventilation (AREA)

Abstract

The invention provides a control method and a control device of a fresh air environmental control unit and the fresh air environmental control unit, wherein the control method comprises the following steps: acquiring a real-time carbon dioxide concentration value of an indoor space and comparing the real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value; when the indoor carbon dioxide concentration is lower than the indoor carbon dioxide concentration threshold value, acquiring outdoor weather data of an area where an indoor space in a preset time period is located, establishing an outdoor temperature prediction model aiming at the preset time period based on the acquired outdoor weather data, and acquiring standard time length Q0 required by introducing rated fresh air volume into the current indoor space; and controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space. According to the invention, peak-valley ventilation regulation can be realized, the fresh air load is reduced, the energy consumption for processing fresh air is reduced, the refrigeration coefficient of the air conditioner in a period is improved, and the purposes of energy conservation and emission reduction are achieved.

Description

Control method and device of fresh air environmental control unit and fresh air environmental control unit
Technical Field
The invention belongs to the technical field of air conditioning, and particularly relates to a control method and device of a fresh air environment-controlled unit and the fresh air environment-controlled unit.
Background
Along with the implementation of the national policy of energy conservation and emission reduction, the requirement of people on comfortable living environment is higher and higher, and along with the strategic goal of double-carbon energy conservation, the comfortable and energy-saving living environment is urgently built.
The existing units for processing the indoor air mainly comprise a fresh air ventilator, an air purifier and the like, the units for processing the indoor air do not distinguish indoor air environments, indoor dirty air and clean air are directly pumped out of a room or mixed with air for air supply, the phenomena of crossing of two air flows, air mixing and the like are caused, the quality of the indoor air is seriously influenced, and the units for processing the indoor air can only carry out real-time ventilation according to the current indoor and outdoor temperature difference, so that the energy-saving effect cannot be achieved. Meanwhile, as the heat insulation performance and the air tightness of the building maintenance structure are improved, the proportion of the indoor introduced fresh air to the total load of the air conditioner is higher and higher, and how to realize high-efficiency energy conservation in the fresh air introduction process is an important measure for building energy conservation in the future.
Disclosure of Invention
Therefore, the invention provides a control method and a control device of a fresh air environmental control unit and the fresh air environmental control unit, and can overcome the defects that the proportion of fresh air introduced indoors to the total load of an air conditioner is high and the device is not efficient and energy-saving because the fresh air environmental control unit cannot process the fresh air introduced outdoors according to the specific conditions of outdoor environmental weather in the prior art.
In order to solve the above problems, the present invention provides a control method for a fresh air environmental control unit, comprising:
acquiring a real-time concentration value of carbon dioxide in an indoor space;
comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
when the real-time carbon dioxide concentration value is lower than the indoor carbon dioxide concentration threshold value,
acquiring outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the acquired outdoor weather data, and acquiring standard time length Q0 required by the current indoor space for introducing rated fresh air volume;
and controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region of the indoor space and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space.
In some embodiments, when the season of the region in which the indoor space is located is summer,
the indoor space temperature interval comprises a summer ventilation temperature area minimum threshold Tx1, a summer ventilation temperature area maximum temperature threshold Tx2 and a summer unit preset temperature Tx0, tx1 is more than Tx0 and is more than Tx2,
and when TSmin is larger than or equal to Tx2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit into a wind mixing mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Tx 2.
In some embodiments, when Tx2 > TSmin ≧ Tx0, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a wind mixing mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model approaches Tx 0.
In some embodiments, when TSmin ≧ Tx2, the operating duration of the corresponding wind mixing mode is Qx1, qx1= Q0; and/or when Tx2 is more than TSmin and is more than or equal to Tx0, the corresponding wind mixing mode operation time length is Qx2, and Qx2= Q0.
In some embodiments, when Tx0 & gtTSmin & gtT & gtTx 1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a full fresh air mode, and controlling the fresh air environmental control unit to operate in a corresponding time period when the temperature of the outdoor temperature prediction model is between Tx1 and Tx 0.
In some embodiments, the total time duration of the time periods corresponding to Tx1 to Tx0 is Qx3, when Qx3 is greater than or equal to Qx0, the fresh air environmental control unit is controlled to operate in the full fresh air mode in the time period when the temperature of the outdoor temperature prediction model approaches Tx1, and the operation time duration is Qx3= Qx0; or,
when Qx3 is less than Qx0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qx3 in a time period that the temperature of the outdoor temperature model is close to Tx1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qxs in a time period that the temperature of the outdoor temperature model is higher than and close to Tx0, and Qxs1= Qx0-Qx3.
In some embodiments, when TSmin < Tx1, the fresh air introducing mode of the fresh air environmental control unit is controlled to be adjusted to be the bypass exhaust mode, and the fresh air environmental control unit is controlled to operate in a time period corresponding to the temperature of the outdoor temperature prediction model being lower than Tx 1.
In some embodiments, the total time duration of the time period corresponding to the time period lower than Tx1 is Qx4, when Qx4 is greater than or equal to Qx0, the fresh air environmental control unit is controlled to operate a bypass exhaust mode in the time period when the temperature of the outdoor temperature prediction model approaches TSmin, and the operation time duration is Qx4= Qx0; or,
the total time length of the time period corresponding to Tx 1-Tx 0 is Qxs2, when Qx4+ Qxs is not less than Qx0, after the fresh air ring control unit is controlled to operate the bypass exhaust mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmin, the fresh air ring control unit is further controlled to operate the full fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is higher than or close to Tx1, and Qxs2 is obtained
=Qx0-Qx4。
In some embodiments, when Qx4+ Qxs < Qx0, after controlling the fresh air environmental control unit to operate the bypass exhaust mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmin, after further controlling the fresh air environmental control unit to operate the fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is higher than and close to the Tx1, qxs = Qx0-Qx4, and further controlling the fresh air environmental control unit to operate the full fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is close to the Tx0, and Qxs = Qx0-Qx 4-Qxs.
In some embodiments, when the season of the region in which the indoor space is located is winter,
the indoor space temperature interval comprises a lowest threshold Td2 of a winter ventilation temperature zone, a highest threshold Td1 of the winter ventilation temperature zone and a preset temperature Td0 of a winter unit, wherein Td2 is less than Td0 and less than Td1,
and when TSmax is less than Td2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit into a mixed air mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Td 2.
In some embodiments, when Td0 is greater than TSmax and is not less than Td2, the fresh air introducing mode of the fresh air environmental control unit is controlled to be adjusted to be the air mixing mode, and the fresh air environmental control unit is controlled to operate in a time period when the temperature of the outdoor temperature prediction model is close to the Td 0.
In some embodiments, when TSmax < Td2, the corresponding wind mixing mode has an operating time period Qd1, qd1= Q0; and/or when the Td0 is more than the TSmax and is more than or equal to the Td2, the corresponding wind mixing mode operation time length is Qd2, and Qd2= Q0.
In some embodiments, when Td1 is greater than TSmax and is not less than Td0, the fresh air introducing mode of the fresh air environmental control unit is controlled to be a full fresh air mode, and the fresh air environmental control unit is controlled to operate in a corresponding time period when the temperature of the outdoor temperature prediction model is between Td0 and Td 1.
In some embodiments, the total time duration of the time periods corresponding to Td0 to Td1 is Qd3, when Qd3 is greater than or equal to Qd0, the fresh air environmental control unit is controlled to operate the full fresh air mode in the time period when the temperature of the outdoor temperature prediction model approaches Td1, and the operation time duration is Qd3= Qd0; or,
when Qd3 is less than Qd0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qd3 in a time period when the temperature of the outdoor temperature model is close to Td1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qds in a time period when the temperature of the outdoor temperature model is higher than and close to Td0, and Qds1= Qd0-Qd3.
In some embodiments, when TSmax is larger than or equal to Td1, the fresh air introducing mode of the fresh air environmental control unit is controlled to be a bypass air exhausting mode, and the fresh air environmental control unit is controlled to operate in a time period corresponding to the time period when the temperature of the outdoor temperature prediction model is lower than Td 1.
In some embodiments, the total time duration of the time period corresponding to the time period shorter than Td1 is Qd4, when Qd4 is greater than or equal to Qd0, the fresh air environmental control unit is controlled to operate a bypass exhaust mode in the time period when the temperature of the outdoor temperature prediction model approaches TSmax, and the operation time duration is Qd4= Qd0; or,
the total time duration of the time period corresponding to Td 0-Td 1 is Qds2, when Qd4+ Qds is more than or equal to Qd0, after the fresh air environmental control unit is controlled to operate the bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, the fresh air environmental control unit is further controlled to operate the full fresh air mode Qds in the time period when the temperature of the outdoor temperature model is higher than or close to the Td1, and Qds2
=Qd0-Qd4。
In some embodiments, when Qd4+ Qds < Qd0, after controlling the fresh air environmental control unit to operate the bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, after further controlling the fresh air environmental control unit to operate the fresh air mode Qds in the time period when the temperature of the outdoor temperature model is higher than and close to the Td1, qds = Qd0-Qd4, and further controlling the fresh air environmental control unit to operate the full fresh air mode Qds in the time period when the temperature of the outdoor temperature model is close to the Td0, and Qds3= Qd0-Qd4-Qd 26 zxft 3926.
The invention also provides a control device of the fresh air environmental control unit, which comprises:
the first acquisition unit is used for acquiring a carbon dioxide real-time concentration value of an indoor space;
the comparison unit is used for comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
the second acquisition unit is used for acquiring outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the acquired outdoor weather data, and acquiring standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
and the execution unit is used for controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature range of the indoor space.
The invention also provides a fresh air environmental control unit, which comprises a processor, a memory and a computer program which is stored on the memory and can run on the processor, wherein the processor realizes the steps of the method when executing the program, or comprises the control device of the fresh air environmental control unit.
According to the control method and device of the fresh air environmental control unit and the fresh air environmental control unit, when the indoor carbon dioxide concentration is lower than the corresponding set threshold, the fresh air environmental control unit can establish an outdoor temperature prediction mode according to outdoor weather data in a certain period, so that the fresh air introduction mode of the fresh air environmental control unit can be controlled and adjusted according to the relation between the minimum temperature TSmin or the maximum temperature TSmax of an outdoor temperature preset model and the indoor space temperature interval, peak-valley ventilation regulation is realized, the fresh air load is reduced, the energy consumption for processing fresh air is reduced, the air conditioning refrigeration coefficient in the period is improved, and the purposes of energy conservation and emission reduction are achieved.
Drawings
FIG. 1 is a schematic diagram of an internal structure of a fresh air environmental control unit according to an embodiment of the present invention;
FIG. 2 is a schematic view illustrating the flow direction of the air flow of the fresh air environmental control unit in FIG. 1 during the full fresh air mode;
FIG. 3 is a schematic view illustrating the flow direction of the air flow of the fresh air environmental control unit in FIG. 1 during the air mixing mode;
FIG. 4 is a schematic view illustrating the flow direction of the air flow of the fresh air environmental control unit in FIG. 1 during the inner circulation mode;
FIG. 5 is a schematic view of the flow direction of the air flow of the fresh air environmental control unit in FIG. 1 during the bypass exhaust mode;
FIG. 6 is a schematic step diagram of a control method for a fresh air environmental control unit according to an embodiment of the present invention;
fig. 7 is a schematic flow chart of control logic of operation in cooling and heating modes of the fresh air environmental control unit according to the embodiment of the present invention;
FIG. 8 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Tx1, tx0, tx2 in summer, and specifically shows the case that TSmin ≧ Tx 2;
FIG. 9 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Tx1, tx0, tx2 in summer, and specifically shows the case where Tx2 > TSmin ≧ Tx 0;
FIG. 10 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Tx1, tx0, tx2 in summer, and specifically shows the case where Tx0 > TSmin ≧ Tx 1;
fig. 11 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Tx1, tx0, and Tx2 in summer, and specifically shows the case that TSmin < Tx 1;
FIG. 12 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Td1, td0, and Td2 in winter, and particularly shows the case of TSmax < Td 2;
FIG. 13 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Td1, td0, and Td2 in winter, and specifically shows the case that Td0 > TSmax ≧ Td 2;
FIG. 14 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Td1, td0, and Td2 in winter, and particularly shows the case that Td1 > TSmin ≧ Td 0;
FIG. 15 is a schematic diagram of the relative relationship between the outdoor temperature preset model and Td1, td0, and Td2 in winter, and specifically shows the case that TSmin ≧ Td 1.
The reference numerals are represented as:
1. an exhaust fan; 2. an electric controller; 3. a bypass exhaust air valve; 4. an exhaust air temperature and humidity sensor; 5. a carbon dioxide sensor; 6. a finned heat exchanger; 7. a fresh air fan; 8. a fresh air outlet; 9. an internal circulation high-efficiency filter; 10. an internal circulation air inlet; 11. an internal circulation air valve; 12. an exhaust inlet; 13. a coarse filter for air exhaust; 14. a total heat exchange core; 15. electrically heating; 16. a fresh air high-efficiency filter; 17. a fresh air coarse filter; 18. a fresh air valve; 19. a fresh air inlet; 20. a fresh air temperature and humidity sensor; 21. and an air exhaust outlet.
Detailed Description
The fresh air environmental control unit shown in fig. 1 comprises an indoor unit and an outdoor unit, a refrigerant pipe is connected between the indoor unit and the outdoor unit, the indoor unit comprises an inner casing body, the inside of the casing body is divided into cavity air ducts through a partition plate, and the cavity air ducts comprise a fresh air channel, an exhaust channel, an internal circulation channel and bypass exhaust air, five air ports are connected outside the inner casing body, a fresh air inlet 19 is connected outside the casing body and used for introducing fresh air, an exhaust outlet 21 is connected outside the casing body and used for exhausting indoor dirty air, an exhaust inlet 12 is connected inside the casing body and used for introducing indoor dirty air, an internal circulation air inlet 10 is connected inside the casing body and used for introducing indoor dirty air, and a fresh air outlet 8 is connected inside the casing body and used for introducing purified fresh air into the casing body.
The fresh air machine is provided with a full fresh air mode, an air mixing mode, an internal circulation mode and a bypass exhaust mode.
A fresh air mode: as shown in fig. 2, the bypass exhaust air valve 3 and the internal circulation air valve 11 are closed. Outdoor fresh air enters a fresh air inlet 19 and passes through a fresh air valve 18, is purified by a fresh air coarse-effect filter 17 and a fresh air high-efficiency filter 16, then enters the total heat exchange core 14 after being electrically heated 15 (the fresh air is started when the temperature of the fresh air is too low, the fresh air is preheated, and the fresh air is prevented from freezing when entering the total heat exchange core 14), is refrigerated or heated by the fin type heat exchanger 6, and is discharged outdoors through a pipeline after passing through a fresh air outlet 8 by a fresh air fan 7. Meanwhile, indoor dirty air enters through the exhaust inlet 12, enters the total heat exchange core 14 after being filtered by the exhaust coarse filter 13, and is exhausted out of the room through the exhaust outlet 21 by the exhaust fan 1 through a pipeline. The fresh air and the dirty air exchange heat and humidity inside the total heat exchange core 14, and the energy-saving effect is achieved.
A wind mixing mode: as shown in fig. 3, the bypass register 3 is closed. Outdoor fresh air enters a fresh air inlet 19 and passes through a fresh air valve 18, is purified by a fresh air coarse-effect filter 17 and a fresh air high-efficiency filter 16, then enters a total heat exchange core 14 after being electrically heated 15 (the fresh air is opened when the temperature is too low, the fresh air is preheated, and the fresh air is prevented from freezing when entering the total heat exchange core 14), meanwhile, indoor dirty air enters through an internal circulation air inlet 10, passes through an internal circulation air valve 11, is purified by an internal circulation high-efficiency filter 9, then is mixed with clean fresh air, is cooled or heated by a fin type heat exchanger 6, and is discharged outdoors through a fresh air outlet 8 by a fresh air fan 7 through a pipeline. Meanwhile, indoor dirty air enters through an exhaust inlet 12, is filtered by an exhaust coarse-effect filter 13, enters a total heat exchange core 14, passes through an exhaust outlet 21 by an exhaust fan 1, and is exhausted out of the room through a pipeline. The fresh air and the dirty air exchange heat and humidity inside the total heat exchange core 14, and the energy-saving effect is achieved.
An internal circulation mode: as shown in fig. 4, the fresh air valve 18 is closed, only the fresh air fan 7 is opened, the exhaust air fan 1 is closed, the internal circulation mode is opened, at this time, indoor dirty air enters through the internal circulation air inlet 10, passes through the internal circulation air valve 11, is purified by the internal circulation high-efficiency filter 9, then is cooled or heated by the fin-type heat exchanger 6, passes through the fresh air outlet 8 by the fresh air fan 7, and is discharged to the outside through a pipeline.
A bypass air exhaust mode: as shown in fig. 5, the internal circulation air valve 11 is closed, and the unit starts a bypass air exhaust mode, in which indoor dirty air is exhausted outdoors without passing through the total heat exchange core 14, so that the energy consumption of the air exhaust fan 1 is reduced, and the unit is more energy-saving.
Referring to fig. 1 to 7 in combination, according to an embodiment of the present invention, there is provided a control method for a fresh air environmental control unit, including:
acquiring a real-time concentration value of carbon dioxide in an indoor space;
comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
when the real-time carbon dioxide concentration value is not lower than the indoor carbon dioxide concentration threshold value, controlling and adjusting the fresh air environmental control unit to enter a fresh air mode;
when the real-time carbon dioxide concentration value is lower than the indoor carbon dioxide concentration threshold value,
the method comprises the steps of obtaining outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the obtained outdoor weather data, and obtaining standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
and controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space.
In the technical scheme, when the indoor carbon dioxide concentration is lower than a corresponding set threshold value, the fresh air environmental control unit can establish an outdoor temperature prediction mode according to outdoor weather data in a certain period (for example, 24 hours in the future), so that the fresh air introduction mode of the fresh air environmental control unit can be controlled and adjusted according to the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the indoor space temperature interval, peak-valley ventilation regulation is realized, the fresh air load is reduced, the energy consumption for processing fresh air is reduced, the air conditioning refrigeration coefficient in the period is improved, and the purposes of energy conservation and emission reduction are achieved.
As shown in fig. 7, after the fresh air environmental control unit (specifically, a fresh air environmental control all-in-one machine, which is hereinafter referred to as a unit for short) is started, an automatic mode is set, and at this time, the unit receives weather forecast data in a future time period from a region where the unit is located, which is processed by the server, through the built-in 5G module. Meanwhile, according to the basic room information set by the initial user, the fresh air quantity required by the unit to control the air quality reaching the standard in the period is judged, and then the ventilation standard time Q0 required by the unit is judged. Meanwhile, the unit acquires real-time indoor and outdoor environment temperature and humidity through a temperature and humidity sensing unit, and comprehensively judges the execution mode of the air conditioner.
After the unit data is collected, the ventilation time period of the air conditioner in the period is judged, then the air conditioner enters the running state, a corresponding concentration sensor (an air box can be specifically adopted) judges whether the concentration of carbon dioxide in the current room is less than 1000ppm or not, and if the concentration of carbon dioxide is more than 1000ppm, the unit executes a full fresh air mode until the concentration of carbon dioxide is reduced to be less than 1000 ppm. And if the concentration of the carbon dioxide is less than 1000ppm, the unit enters an operation mode for judgment, and if no user intervention is set, the unit executes a fresh air energy-saving operation mode according to the forecast weather model. When the unit does not carry out the fresh air mode and does not introduce fresh air, the unit judges whether to carry out the operation of the cooling or heating mode according to whether the current indoor environment temperature reaches the temperature set point. If the temperature in the room reaches the set value, the unit closes the compressor and enters a shutdown state. The fresh air energy-saving operation mode is a mode for controlling and adjusting fresh air among a fresh air mode, a mixed air mode and a bypass air exhaust mode, the server predicts the weather of the region where the unit is located in the future period, establishes the weather data in the period, receives the weather data through the 5G module arranged in the unit, establishes an outdoor temperature prediction model, and simultaneously, the unit judges the rated fresh air volume of the current room according to the room information set by the user.
Specifically, in one embodiment, when the season of the region in which the indoor space is located is summer,
the indoor space temperature interval comprises a summer ventilation temperature area minimum threshold Tx1, a summer ventilation temperature area maximum temperature threshold Tx2 and a summer unit preset temperature Tx0, tx1 is larger than Tx0 and smaller than Tx2, as shown in FIG. 8, when TSmin is larger than or equal to Tx2, the fresh air introducing mode of the fresh air environmental control unit is controlled and adjusted to be a mixed air mode, and the fresh air environmental control unit is controlled to operate in a time period when the temperature of the outdoor temperature prediction model is close to Tx2, so that the introduced fresh air heat load is as low as possible, and the temperature of the indoor space is prevented from bringing adverse fluctuation. In the technical scheme, the outdoor temperature is high, the lowest temperature of the environment exceeds the highest temperature in the unit model, the room load is large at the moment, and the fresh air introducing requirement is realized through the air mixing mode on the premise of meeting the requirements of introducing fresh air and maintaining the comfort level of the room.
In some embodiments, referring to fig. 9, when Tx2 > TSmin ≧ Tx0, the fresh air introducing mode of the fresh air environmental control unit is controlled to be adjusted to be the air mixing mode, and the fresh air environmental control unit is controlled to operate in a time period when the temperature of the outdoor temperature prediction model approaches Tx0, so that the heat load of the introduced fresh air is as low as possible, and the temperature of the indoor space is prevented from being adversely fluctuated.
Preferably, when TSmin is larger than or equal to Tx2, the running time of the corresponding wind mixing mode is Qx1, and Qx1= Q0; and/or when Tx2 is more than TSmin and is more than or equal to Tx0, the corresponding air mixing mode operation time length is Qx2, and Qx2= Q0, so that the introduction amount of fresh air is ensured.
In some embodiments, referring to fig. 10, when Tx0 > TSmin ≧ Tx1, the fresh air introducing mode of the fresh air environmental control unit is controlled to be adjusted to the full fresh air mode, and the fresh air environmental control unit is controlled to operate in a time period corresponding to the temperature of the outdoor temperature prediction model between Tx1 and Tx 0. Specifically, the total time duration of the time periods corresponding to Tx1 to Tx0 is Qx3, when Qx3 is greater than or equal to Qx0, it indicates that the introduction time of the fresh air mode is enough for fresh air demand, at this time, the fresh air environmental control unit is controlled to operate the fresh air mode in the time period when the temperature of the outdoor temperature prediction model is close to Tx1, and the operation time duration is Qx3= Qx0; when Qx3 is less than Qx0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qx3 in a time period when the temperature of the outdoor temperature model is close to Tx1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qxs in a time period when the temperature of the outdoor temperature model is higher than or close to Tx0, and Qxs1= Qx0-Qx3, namely when Qx3 is less than Qx0, the full fresh air mode is preferentially operated, and then the mixed air mode is operated.
In some embodiments, referring to fig. 11, when TSmin < Tx1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a bypass exhaust mode, and controlling the fresh air environmental control unit to operate in a time period corresponding to the temperature of the outdoor temperature prediction model being lower than Tx1, further, a total duration of the time period corresponding to the time period lower than Tx1 is Qx4, and when Qx4 is greater than or equal to Qx0, controlling the fresh air environmental control unit to operate in the bypass exhaust mode in a time period when the temperature of the outdoor temperature prediction model is close to TSmin, and the operation duration is Qx4= Qx0; or the total time length of the time period corresponding to Tx 1-Tx 0 is Qxs2, when Qx4+ Qxs is not less than Qx0, after the fresh air environmental control unit is controlled to operate the bypass exhaust mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to TSmin, the fresh air environmental control unit is further controlled to operate the full fresh air mode Qxs in the time period when the temperature of the outdoor temperature prediction model is higher than or close to Tx1, and Qxs = Qx0-Qx4, namely, the bypass exhaust mode is preferably operated at the time, heat recovery is not needed, the exhaust resistance is reduced, the exhaust efficiency is improved, and when the bypass exhaust mode is insufficient, the full fresh air mode is further operated.
In some embodiments, when Qx4+ Qxs < Qx0, after controlling the fresh air environmental control unit to operate the bypass exhaust mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmin, and after controlling the fresh air environmental control unit to operate the fresh air mode Qxs in the time period when the temperature of the outdoor temperature prediction model is higher than and close to the Tx1, qxs = Qx0-Qx4, and further controlling the fresh air environmental control unit to operate the full fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is close to the Tx0, and Qxs3= Qx0-Qx4-Qxs, that is, the bypass exhaust mode is preferably operated at this time, heat recovery is not required, the exhaust resistance is reduced, the exhaust efficiency is improved, when the bypass exhaust mode is insufficient, the fresh air mode is further operated, and the fresh air mode cannot operate the load demand (the last mixed air mode) is not enough.
In another embodiment, when the season of the region in which the indoor space is located is winter,
the indoor space temperature interval includes a lowest threshold Td2 of a ventilation temperature zone in winter, a highest threshold Td1 of the ventilation temperature zone in winter, and a preset temperature Td0 of the winter unit, where Td2 < Td0 < Td1, as shown in fig. 12, when TSmax < Td2, the fresh air introducing mode of the fresh air environmental control unit is controlled and adjusted to be a mixed air mode, and the fresh air environmental control unit is controlled to operate in a time period when the temperature of the outdoor temperature prediction model approaches Td2, so as to make the introduced fresh air heat load (cold) as low as possible and prevent the introduced fresh air heat load (cold) from bringing adverse fluctuation to the temperature of the indoor space. According to the technical scheme, the outdoor temperature is low, the highest environmental temperature is lower than the lowest temperature in the unit model, the room load is large at the moment, and the fresh air introducing requirement is achieved through the air mixing mode on the premise that the introduction of fresh air and the maintenance of the room comfort level are met.
In some embodiments, referring to fig. 13, when Td0 > TSmax ≧ Td2, the fresh air introducing mode of the fresh air environmental control unit is controlled to be adjusted to be the air mixing mode, and the fresh air environmental control unit is controlled to operate in a time period when the temperature of the outdoor temperature prediction model approaches Td0, so that the introduced fresh air cooling load is as low as possible, and the adverse fluctuation of the temperature of the indoor space is prevented.
In some embodiments, when TSmax < Td2, the corresponding wind mixing mode has an operating time period Qd1, qd1= Q0; and/or when the Td0 is more than the TSmax and is more than or equal to the Td2, the corresponding wind mixing mode operation time length is Qd2, and Qd2= Q0.
In some embodiments, referring to fig. 14, when Td1 > TSmax ≧ Td0, the control adjusts the fresh air introducing mode of the fresh air environmental control unit to be the full fresh air mode, and controls the fresh air environmental control unit to operate in a corresponding time period when the temperature of the outdoor temperature prediction model is between Td0 and Td 1. Specifically, the total time duration of the time period corresponding to Td 0-Td 1 is Qd3, when Qd3 is greater than or equal to Qd0, it indicates that the introduction time of the fresh air mode is enough for fresh air demand, the fresh air environmental control unit is controlled to operate the fresh air mode in the time period when the temperature of the outdoor temperature prediction model approaches Td1, and the operation time duration is Qd3= Qd0; when Qd3 is less than Qd0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qd3 in a time period when the temperature of the outdoor temperature model is close to Td1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qds in a time period when the temperature of the outdoor temperature model is higher than or close to Td0, and Qds1= Qd0-Qd3, namely when Qd3 is less than Qd0, the full fresh air mode is preferentially operated, and then the mixed air mode is operated.
In some embodiments, referring to fig. 15, when TSmax is greater than or equal to Td1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a bypass exhaust mode, and controlling the fresh air environmental control unit to operate in a time period corresponding to the temperature of the outdoor temperature prediction model being lower than Td1, further, a total time length of the time period corresponding to the time period lower than Td1 is Qd4, and when Qd4 is greater than or equal to Qd0, controlling the fresh air environmental control unit to operate in the bypass exhaust mode in a time period when the temperature of the outdoor temperature prediction model is close to TSmax, and the operation time length is Qd4= Qd0; or the total time duration of the time period corresponding to the Td 0-Td 1 is Qds, when the Qd4+ Qds is more than or equal to the Qd0, after the fresh air environmental control unit is controlled to operate the bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, the fresh air environmental control unit is further controlled to operate the full fresh air mode Qds in the time period when the temperature of the outdoor temperature prediction model is higher than and close to the Td1, and Qds = Qd0-Qd4, namely, the bypass exhaust mode is preferably operated at the moment, heat recovery is not needed, the exhaust resistance is reduced, the exhaust efficiency is improved, and when the bypass exhaust mode is insufficient, the full fresh air mode is further operated.
In some embodiments, when Qd4+ Qds < Qd0, after controlling the fresh air environmental control unit to operate the bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, and further controlling the fresh air environmental control unit to operate the fresh air mode Qds in the time period when the temperature of the outdoor temperature model is higher than and close to the Td1, qds = Qd0-Qd4, and further controlling the fresh air environmental control unit to operate the full fresh air mode Qds in the time period when the temperature of the outdoor temperature model is close to the Td0, and Qds3= Qd0-Qd4-Qds, that is, the bypass exhaust mode is preferably operated at this time, heat recovery is not required, the exhaust resistance is reduced, the exhaust efficiency is improved, when the bypass exhaust mode is insufficient, the fresh air mode is further operated, and the fresh air mode cannot operate the final mixing mode (load requirement cannot be satisfied).
It should be noted that in winter, no matter what specific fresh air introduction mode exists, as long as TS is less than or equal to the electric heating trigger temperature value, the electric heating can be started.
It should be noted that the approach to a certain temperature in the present invention may specifically be a certain difference (e.g. 1 ℃) above or below the certain temperature, and may specifically be set reasonably according to the climate of the corresponding region.
The Q0 is the ventilation time calculated based on the room volume and the indoor air quality requirement, the total ventilation quantity required according to the room information and the rated air quantity of the unit are fixed values, and the division of the total ventilation quantity and the rated air quantity is the Q0. In the invention, under various fresh air introducing modes, the ventilation requirement of a room can be met only by selecting the optimal ventilation time period under the established model and overlapping the optimal ventilation time period to be equal to Q0.
According to an embodiment of the present invention, there is also provided a control device for a fresh air environmental control unit, including:
the first acquisition unit is used for acquiring a carbon dioxide real-time concentration value of an indoor space;
the comparison unit is used for comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
the second acquisition unit is used for acquiring outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the acquired outdoor weather data, and acquiring standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
and the execution unit is used for controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature range of the indoor space.
According to an embodiment of the present invention, there is also provided a fresh air environmental control unit, including a processor, a memory, and a computer program stored in the memory and operable on the processor, where the processor implements the steps of the method when executing the program, or includes the control device of the fresh air environmental control unit.
It is readily understood by a person skilled in the art that the advantageous ways described above can be freely combined, superimposed without conflict.
The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention. The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several improvements and modifications can be made without departing from the technical principle of the present invention, and these improvements and modifications should also be regarded as the protection scope of the present invention.

Claims (18)

1. A control method of a fresh air environmental control unit is characterized by comprising the following steps:
acquiring a real-time concentration value of carbon dioxide in an indoor space;
comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
when the real-time carbon dioxide concentration value is lower than the indoor carbon dioxide concentration threshold value,
the method comprises the steps of obtaining outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the obtained outdoor weather data, and obtaining standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
controlling and adjusting a fresh air introducing mode of a fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space;
when the season of the region where the indoor space is located is summer,
the indoor space temperature interval comprises a summer ventilation temperature area minimum threshold Tx1, a summer ventilation temperature area maximum temperature threshold Tx2 and a summer unit preset temperature Tx0, tx1 is more than Tx0 and is more than Tx2,
when TSmin is larger than or equal to Tx2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a wind mixing mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Tx 2;
when TSmin is larger than or equal to Tx2, the operation time of the corresponding wind mixing mode is Qx1, and Qx1= Q0.
2. The control method according to claim 1,
when Tx2 is more than TSmin and is more than or equal to Tx0, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a wind mixing mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Tx 0.
3. The control method according to claim 2,
when Tx2 > TSmin ≧ Tx0, the corresponding mixed-air mode operation duration is Qx2, and Qx2= Q0.
4. The control method according to claim 1,
when Tx0 is larger than TSmin and is larger than or equal to Tx1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a full fresh air mode, and controlling the fresh air environmental control unit to operate in a corresponding time period when the temperature of the outdoor temperature prediction model is between Tx1 and Tx 0.
5. The control method according to claim 4,
the total time duration of the time periods corresponding to Tx 1-Tx 0 is Qx3, when the Qx3 is more than or equal to Qx0, the fresh air environmental control unit is controlled to operate in a full fresh air mode in the time period when the temperature of the outdoor temperature prediction model is close to Tx1, and the operation time duration is Qx3= Qx0; or,
when Qx3 is less than Qx0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qx3 in a time period that the temperature of the outdoor temperature model is close to Tx1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qxs in a time period that the temperature of the outdoor temperature model is higher than and close to Tx0, and Qxs1= Qx0-Qx3.
6. The control method according to claim 1,
and when TSmin is less than Tx1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a bypass air exhaust mode, and controlling the fresh air environmental control unit to operate in a time period corresponding to the time period when the temperature of the outdoor temperature prediction model is lower than Tx 1.
7. The control method according to claim 6,
the total time period corresponding to the time period lower than Tx1 is Qx4, when Qx4 is more than or equal to Qx0, the fresh air environmental control unit is controlled to operate a bypass air exhaust mode in the time period when the temperature of the outdoor temperature prediction model is close to TSmin, and the operation time period is Qx4= Qx0; or,
the total time length of a time period corresponding to Tx 1-Tx 0 is Qxs2, when Qx4+ Qxs is not less than Qx0, after the fresh air ring control unit is controlled to operate a bypass exhaust mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to TSmin, the fresh air ring control unit is further controlled to operate a full fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is higher than or close to Tx1, and Qxs2= Qx0-Qx4.
8. The control method according to claim 7, wherein when Qx4+ Qxs < Qx0, after controlling the fresh air loop control unit to operate the bypass ventilation mode Qx4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmin, qxs = Qx0-Qx4 after controlling the fresh air loop control unit to operate the fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is higher than and close to the Tx1, and further controlling the fresh air loop control unit to operate the full fresh air mode Qxs in the time period when the temperature of the outdoor temperature model is close to the Tx0, and Qxs = Qx0-Qx 4-Qxs.
9. A control method of a fresh air environment control unit is characterized by comprising the following steps:
acquiring a real-time carbon dioxide concentration value of an indoor space;
comparing the obtained real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
when the real-time carbon dioxide concentration value is lower than the indoor carbon dioxide concentration threshold value,
the method comprises the steps of obtaining outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the obtained outdoor weather data, and obtaining standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
controlling and adjusting a fresh air introducing mode of a fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space;
when the season of the region where the indoor space is located is winter,
the indoor space temperature interval comprises a lowest threshold Td2 of a winter ventilation temperature zone, a highest threshold Td1 of the winter ventilation temperature zone and a preset temperature Td0 of a winter unit, wherein Td2 is less than Td0 and less than Td1,
when TSmax is less than Td2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a mixed air mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to the Td 2;
when TSmax < Td2, the operation time period of the corresponding wind mixing mode is Qd1, qd1= Q0.
10. The control method according to claim 9,
and when Td0 is more than or equal to TSmax and is more than or equal to Td2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit into a wind mixing mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Td 0.
11. The control method according to claim 10,
when Td0 is larger than TSmax and larger than or equal to Td2, the corresponding operation time length of the air mixing mode is Qd2, and Qd2= Q0.
12. The control method according to claim 9,
and when Td1 is more than the TSmax and is not less than Td0, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a full fresh air mode, and controlling the fresh air environmental control unit to operate in a corresponding time period when the temperature of the outdoor temperature prediction model is between Td0 and Td 1.
13. The control method according to claim 12,
the total time period corresponding to the Td 0-Td 1 is Qd3, when the Qd3 is more than or equal to the Qd0, the fresh air environmental control unit is controlled to operate a full fresh air mode in the time period when the temperature of the outdoor temperature prediction model approaches to the Td1, and the operation time period is Qd3= Qd0; or,
when Qd3 is less than Qd0, after the fresh air environmental control unit is controlled to operate a full fresh air mode Qd3 in a time period when the temperature of the outdoor temperature model is close to Td1, the fresh air environmental control unit is further controlled to operate a mixed air mode Qds in a time period when the temperature of the outdoor temperature model is higher than and close to Td0, and Qds1= Qd0-Qd3.
14. The control method according to claim 9,
when TSmax is larger than or equal to Td1, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a bypass air exhausting mode, and controlling the fresh air environmental control unit to operate in a time period corresponding to the time period when the temperature of the outdoor temperature prediction model is lower than Td 1.
15. The control method according to claim 14,
the total time period corresponding to the time period shorter than Td1 is Qd4, when Qd4 is more than or equal to Qd0, the fresh air environmental control unit is controlled to operate a bypass exhaust mode in the time period when the temperature of the outdoor temperature prediction model is close to TSmax, and the operation time period is Qd4= Qd0; or,
the total time length of a time period corresponding to Td 0-Td 1 is Qds2, when Qd4+ Qds is greater than or equal to Qd0, after the fresh air environmental control unit is controlled to operate a bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, the fresh air environmental control unit is further controlled to operate a full fresh air mode Qds in the time period when the temperature of the outdoor temperature model is higher than or close to the Td1, and Qds = Qd0-Qd4.
16. The control method of claim 15, wherein when Qd4+ Qds < Qd0, after controlling the fresh air environmental control unit to operate the bypass exhaust mode Qd4 in the time period when the temperature of the outdoor temperature prediction model is close to the TSmax, after further controlling the fresh air environmental control unit to operate the fresh air mode Qds in the time period when the temperature of the outdoor temperature model is higher than and close to the Td1, qds2= Qd0-Qd4, and further controlling the fresh air environmental control unit to operate the full fresh air mode Qds in the time period when the temperature of the outdoor temperature model is close to the Td0, and Qds = Qd0-Qd 4-Qds.
17. The utility model provides a controlling means of new trend environmental control unit which characterized in that includes:
the first acquisition unit is used for acquiring a carbon dioxide real-time concentration value of an indoor space;
the comparison unit is used for comparing the acquired real-time carbon dioxide concentration value with an indoor carbon dioxide concentration threshold value;
the second acquisition unit is used for acquiring outdoor weather data of a region where the indoor space is located in a preset time period, establishing an outdoor temperature prediction model aiming at the preset time period based on the acquired outdoor weather data, and acquiring standard time length Q0 required by introducing rated fresh air volume into the current indoor space;
the execution unit is used for controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit according to the season of the region where the indoor space is located and based on the relation between the minimum temperature TSmin or the maximum temperature TSmax of the outdoor temperature preset model and the temperature interval of the indoor space; when the season of the region where the indoor space is located is summer,
the indoor space temperature interval comprises a summer ventilation temperature area minimum threshold Tx1, a summer ventilation temperature area maximum temperature threshold Tx2 and a summer unit preset temperature Tx0, tx1 is more than Tx0 and is more than Tx2,
when TSmin is larger than or equal to Tx2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a wind mixing mode, controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to Tx2, and when TSmin is larger than or equal to Tx2, controlling the operation time of the corresponding wind mixing mode to be Qx1, wherein Qx1= Q0; or, when the season of the region where the indoor space is located is winter,
the indoor space temperature interval comprises a lowest threshold Td2 of a winter ventilation temperature zone, a highest threshold Td1 of the winter ventilation temperature zone and a preset temperature Td0 of a winter unit, wherein Td2 is less than Td0 and less than Td1,
when TSmax is less than Td2, controlling and adjusting a fresh air introducing mode of the fresh air environmental control unit to be a mixed air mode, and controlling the fresh air environmental control unit to operate in a time period when the temperature of the outdoor temperature prediction model is close to the Td 2;
when TSmax < Td2, the operation time period of the corresponding wind mixing mode is Qd1, qd1= Q0.
18. A fresh air environmental control unit comprising a processor, a memory, and a computer program stored in the memory and operable on the processor, the processor executing the program to perform the steps of the method of any of claims 1 to 16, or a control means for the fresh air environmental control unit according to claim 17.
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